Wireless network security research proposal

Research and Academics | Cisco Research Center

the research platforms are meant to support fundamental, pre-competitive academic research, for which impacts may very well be realized 10 or more years into the future, i. deployed, the platforms will address pre-competitive research challenges on at-scale research platforms, increasing education about wireless technologies and data networking, increasing academic-industry cooperative partnerships, and accelerating technology commercialization and transfer from academia to industry. we do expect the research platforms to cover a wide range of emerging research areas. relating to the requests for proposals that will be released by the ppo:What is the role of ppo in the design of the research platforms? control for pervasive computing informationresearcher:Peter steenkisteaccountable mobile computing framework based on user behavior modelingresearch area: secure home computing | mobility | privacy protection | trustworthy computing platforms and devicescross cutting thrusts: next generation threat prediction and response | threat analysis and modelingresearchers:Martin griss, anind dey, joy zhangadaptive beamforming for anti-jamming and assured network communicationsresearch area: next generation secure and available networksresearchers:Patrick tague, jason lohn, derek lindenadaptive strategies for cross-layer jamming and anti-jammingresearch area: next generation secure and available networkscross cutting thrusts: threat analysis and modeling | next generation threat prediction and responseresearcher:Patrick tagueadding artificial intelligence to facial matching using soft-biometric attributesresearch area: security of cyber-physical systemsresearcher:Marios savvidesadvancing logic-based access controlresearch area: secure home computingcross cutting thrusts: formal methods | usable privacy and securityresearcher:Lujo baueragora: mobile cloud-computing middlewareresearch area: mobilityresearcher:Priya narasimhananalyzing the threat dynamics of complex networked systemsresearch area: survivable distributed systemscross cutting thrusts: threat analysis and modelingresearchers:Andrew moore, timothy shimeallandroid app scanner research area: mobilitycross cutting thrusts: usable privacy and securityresearchers:Jason hong, janne lindqvistan experiment in hiring discrimination via online social networksresearch area: privacy protectionresearchers:Alessandro acquisti, christina fongapplying computational learning theoryresearcher:Avrim blumarchitectural support for scalable program checkpointingresearchers:Babak falsafiare there evolutionary roots to privacy concerns? the ppo will collaborate closely with nsf, the wireless research community, local communities, and industry, in part through the industry consortium, in the design, development, deployment, and initial operations of the research platforms.0 million wireless program from nsf to fund city, university research hubs. will be a minimum of 6-7 likely platform research topics, each spanning a broad research area. anticipates issuing a solicitation calling for proposals from the academic community to support basic research on the platforms by early 2020. however, as a critical mass of individuals is needed to test the research platforms (specific user densities are required to validate any testing), small cities/communities must demonstrate the presence of appropriate user densities that the follow-on research may require as part of the corresponding proposal. with any system, there will be a learning curve – but it is anticipated that the research platforms will have staff and tutorials to assist users and mitigate this learning curve. he will oversee the process of research allocation on the platforms as well as the evolution of platform research focus over time. will oversee the overall pawr technical direction, platform architectures, and alignment with the pawr vision of developing a shared, open, usable, diverse experimental facility that will support groundbreaking research in wireless networking. will be a minimum of 6-7 likely platform research topics, each spanning a broad research area. can industry contribute to a proposal without being part of the industry consortium described in the solicitation? carriers, device and equipment vendors, and researchers around the world are looking toward the next generation of wireless technologies (popularly called ‘5g’) and beyond to support this unparalleled growth in devices and traffic. experimental research platforms will allow researchers to validate cutting-edge technologies (e. platforms for advanced wireless research (pawr) program is a joint effort by the national science foundation and a wireless industry consortium to create city-scale testing platforms to accelerate fundamental research on wireless communication and networking technologies. federally-funded research and development centers (ffrdcs) participate in the design, development, and deployment of the research platforms and/or in conducting experiments on the research platforms once they are operational?

Framework for wireless network security using quantum cryptography

for-profit and non-profit partners are welcomed (and in fact, encouraged) to the extent that they enhance the capabilities, reach, and sustainability of a proposed research platform.. proposals will be reviewed by a research committee (of which the ppo is a member) to ensure research conducted on the platforms aligns with the goals of the pawr program. platforms for advanced wireless research (pawr) program is a joint effort by the national science foundation and a wireless industry consortium to create city-scale testing platforms to accelerate fundamental research on wireless communication and networking technologies. is a nonprofit organization that spurs the creation of next-generation applications and services that leverage advanced networking technologies that build the foundation for smart communities. are some of the platform research topics likely to be? what spectrum bands are the research platforms expected to operate, and will there be a need for licensing? these research platforms constitute research infrastructures for the wireless networking and communications research community.0 million wireless program from nsf to fund city, university research hubs. will serve as examples of smart and connected community networks that demonstrate potential applications/services including cyber-physical systems, cyber-security, internet of things, robotics, smart and connected health, and big data. do you envision these research platforms interacting with corporate (e. research platforms will be built on software-defined radios – devices capable of operating across multiple radio frequencies and connected via a programmable back-end network infrastructure with access to high-speed network connectivity such as internet2 or other backhaul (i. proposers are expected to obtain such licenses and include these as part of their proposals to validate the feasibility of the proposed research platforms to work in the bands to be supported. nsf nor the ppo will predefine the research foci for the research platforms. page is a list of all current CyLab research projects by project name. research platforms are expected to serve the research communities for a decade or more, but the individual research projects that will be conducted on the research platforms can be short-, medium-, and/or long-term.., to support fundamental, pre-competitive research with the goal of quickly identifying technologies with potential commercialization opportunities). in internet traffic place never-before-imagined demands on conventional 4g lte networks and public wifi networks, which may not be able to keep pace with the growing demand. the last year, a new industry consortium comprising more than 25 leading networking vendors, device manufacturers, and wireless carriers has been established to support the pawr effort, garnering approximately million in cash and in-kind contributions. similarly, ffrdcs and federal labs may participate in conducting experiments on the eventual research platforms.

Platforms for Advanced Wireless Research (PAWR) Project Office

there be review criteria for the research platform proposals that go beyond the technical details of setting up the research platforms?, given the scale of these research platforms, we anticipate such teaming arrangements. past efforts such as geni and related cise research infrastructure projects have demonstrated that providing active user support is critical to ensuring widespread user adoption.-area whitespace to utilize novel whitespace-based wireless networks to design, build and demonstrate 1gbps connectivity to remote locations via long-range wireless mesh connections. will seek proposed platforms that have the capability to support a minimum number of research topic areas (e. plans to address this requirement will be a key review criterion in the evaluation of future research platform proposals (to be submitted in response to rfps). relating to the requests for proposals that will be released by the ppo:What is the role of ppo in the design of the research platforms? research platforms will be built on software-defined radios – devices capable of operating across multiple radio frequencies and connected via a programmable back-end network infrastructure with access to high-speed network connectivity such as internet2 or other backhaul (i. can industry contribute to a proposal without being part of the industry consortium described in the solicitation? multiple universities form a team to apply for a research platform? will provide leadership, guidance, and outreach to academic wireless researchers nationwide to solicit feedback on platform design, and integrate the needs of research into ppo operations. there a general sense of the geographic area to be covered by these research platforms (i. designing, developing, deploying, and operating the platforms for advanced wireless research:The ppo, in conjunction with the pawr industry consortium and nsf, is developing a request for proposals (rfp) that will call for teams of communities and research universities to propose the design, development, deployment, and initial operations of multiple platforms for advanced wireless research across the country. plans to address this requirement will be a key review criterion in the evaluation of future research platform proposals (to be submitted in response to rfps). the focus on pre-competitive research, we expect the outcomes from these research platforms to feed into corporate/private testbeds that focus on competitive research and associated intellectual property (ip) attributes. platforms for advanced wireless research (pawr) rfp is now live! these research platforms constitute research infrastructures for the wireless networking and communications research community. will serve as examples of smart and connected community networks that demonstrate potential applications/services including cyber-physical systems, cyber-security, internet of things, robotics, smart and connected health, and big data. terms of team structure, whom do you anticipate leading the teams charged with designing, developing, and deploying the research platforms (e.

A Proposal of Anonymous IEEE802.1X Authentication Protocol for

, these pawr research efforts will accelerate the deployment of a new generation of super-fast, ultra-low latency, high-capacity networks will enable breakthrough applications for consumers, smart cities, and the internet of things that cannot even be imagined today. the pawr effort aims to explore research at scale in real-world settings outside of the laboratory., staying current with rapidly evolving technologies will be essential to the long-term utility and success of the research platforms, including sustenance. do you maintain mid- and long-term research projects while also accounting for public interest and the need to translate innovations to the marketplace quickly in order to justify local investment? year, following receipt of proposals in response to the rfp, the ppo will run a merit review process, comparable to that of nsf, to evaluate the submitted proposals. there an expectation that the research conducted on the platforms will inherently lead to commercialization in the short term? would you characterize the research platforms and how many will there be? first part of the pawr program is constituted by building the research platforms, which will involve a mix of engineering as well as research in infrastructure. pawr industry consortium members are not eligible to be named participants on any research platform proposal. allocations to nsf-supported researchers will advance fundamental knowledge in the long term, while allocations to industry researchers will accelerate nearer-term research and development activities. we only think about short-term (three years or less until commercialization) projects to evaluate on the research platforms envisioned in the pawr: ppo program solicitation? do you envision these research platforms interacting with corporate (e. also expect that these research platforms will act as fertile testing grounds for large-scale validation of industry equipment/algorithms/architectures that may not be feasible with smaller private testbeds. terms of team structure, whom do you anticipate leading the teams charged with designing, developing, and deploying the research platforms (e. we have provided sample research areas, but these are meant to be only examples. you envision following an approach by which experiments to be run on the research platforms are vetted in some way to determine their suitability? federally-funded research and development centers (ffrdcs) participate in the design, development, and deployment of the research platforms and/or in conducting experiments on the research platforms once they are operational? have announced the release of the pawr program’s preliminary request for proposals (rfp) – responses are due on june 1, 2017 at 6 pm eastern time. for academic or municipal leaders interested in submitting a pawr proposal, we anticipate hosting a proposers’ day in the washington, dc, area after the pawr rfp is announced.

Research Projects - Carnegie Mellon University CyLab

announcement of the subawardees for the first research platforms is anticipated early next year (2018). past efforts such as geni and related cise research infrastructure projects have demonstrated that providing active user support is critical to ensuring widespread user adoption., developing, deploying, and operating the platforms for advanced wireless research:Within less than four months of its establishment (i. and beyond: national science foundation plunks down million for advanced wireless research. companies will benefit by: helping to sustain us industry leadership; shaping design of research platforms; and securing cutting-edge research returns well in excess of initial investment. are all critical questions that research in advanced networking should address. the second part of the program will entail support for fundamental and applied research to be conducted on the research platforms., given the scale of these research platforms, we anticipate such teaming arrangements. will notify and educate communities about the opportunity to host a pawr wireless research platform and will work to motivate local governments to respond to the pawr rfp. also expect that these research platforms will act as fertile testing grounds for large-scale validation of industry equipment/algorithms/architectures that may not be feasible with smaller private testbeds. platforms for advanced wireless research (pawr) program is jointly supported by the national science foundation and a wireless industry consortium to create community-scale research platforms to accelerate fundamental research on wireless communication and networking technologies.., to support fundamental, pre-competitive research with the goal of quickly identifying technologies with potential commercialization opportunities). answer to this question may vary depending on the goals and scope of each individual research platform. intent is for the research platforms to feature both open hardware and open software interfaces, and to be reusable by others. are all critical questions that research in advanced networking should address. allocation of time will be shared equally between industry and nsf-supported academic researchers and will be complementary. local corporate sponsors participate in the city-university research platform (design, development, and deployment) proposals? the fcc website for receiving applications to this new experimental license is expected to be online by the time the proposals for platforms are due. conducted on pawr platforms will advance robust new wireless devices, communication techniques, networks, systems, and services that will revolutionize the nation’s wireless ecosystem. Resume for restaurant hostess position

Key factors for effective research proposals in power engineering

a few sample topic areas among these could be:Mmwave to enable r&d and systems testing at the millimeter-wave bands between 20 ghz and 200 ghz, with a target of 100 gbps in data rates for small-cell networks that cover a few city blocks. a few sample topic areas among these could be:Mmwave to enable r&d and systems testing at the millimeter-wave bands between 20 ghz and 200 ghz, with a target of 100 gbps in data rates for small-cell networks that cover a few city blocks. there be review criteria for the research platform proposals that go beyond the technical details of setting up the research platforms? are some of the platform research topics likely to be? there any expectations as far as open interfaces for the research platforms? there been thought as to how to make the research platforms “living”/dynamically adaptable?, developing, deploying, and operating the platforms for advanced wireless research:Within less than four months of its establishment (i.. proposals will be reviewed by a research committee (of which the ppo is a member) to ensure research conducted on the platforms aligns with the goals of the pawr program. however, as a critical mass of individuals is needed to test the research platforms (specific user densities are required to validate any testing), small cities/communities must demonstrate the presence of appropriate user densities that the follow-on research may require as part of the corresponding proposal. to test data network architectures for next-generation networks that operate with a wireless edge. it is anticipated that each subsequently-funded research platform will comprise a city-university team; this team may also involve corporate partners, ffrdcs, and federal labs. for academic or municipal leaders interested in submitting a pawr proposal, we anticipate hosting a proposers’ day in the washington, dc, area after the pawr rfp is announced. will provide leadership, guidance, and outreach to academic wireless researchers nationwide to solicit feedback on platform design, and integrate the needs of research into ppo operations. will be able to take advantage of the multi-use capability of the research platform by “plugging in” additional experimental technologies. spectrum to focus on the spectral bands that are sub-6ghz, and aim to identify spectral opportunities in existing networks and establish usage models for novel spectrum-driven applications, while also studying co-existence and protection issues. ppo is responsible for allocating and managing time for experimentation on the platforms for advanced wireless research. industry consortium members may not participate in platform proposals, given their role in funding the platforms; other companies may choose to collaborate directly with the individual proposers. year, following receipt of proposals in response to the rfp, the ppo will run a merit review process, comparable to that of nsf, to evaluate the submitted proposals. have announced the release of the pawr program’s preliminary request for proposals (rfp) – responses are due on june 1, 2017 at 6 pm eastern time. Resume too many pages

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will notify and educate communities about the opportunity to host a pawr wireless research platform and will work to motivate local governments to respond to the pawr rfp., non-profits are eligible to apply as leads for research platform proposals. are several problems of interest to rural areas that a small city/community may consider tackling as part of a research platform. each research platform will also have an external user advisory council to provide continued inputs on the research scope and foci of the platforms during the operations of the platforms. metrology to advance capabilities to measure and monitor wireless network performance and support research on methods to improve the security, reliability and performance of wireless networks. a city or a university may lead a proposing team; each proposal must make the case that the lead is capable of following through on the design, development, deployment, and operation of the proposed research platform. we do expect the research platforms to cover a wide range of emerging research areas. there a general sense of the geographic area to be covered by these research platforms (i. relating to the research to be enabled by the research platforms:Is it incumbent on potential users to learn how to use the research platform interfaces or will there be tutorials created/support provided? the ppo will collaborate closely with nsf, the wireless research community, local communities, and industry, in part through the industry consortium, in the design, development, deployment, and initial operations of the research platforms. one do research on the design and development of the research platforms, or only as part of research projects to be enabled by the research platforms? metrology to advance capabilities to measure and monitor wireless network performance and support research on methods to improve the security, reliability and performance of wireless networks. the focus on pre-competitive research, we expect the outcomes from these research platforms to feed into corporate/private testbeds that focus on competitive research and associated intellectual property (ip) attributes. for a given research platform, the geographic area will be a function of the type of wireless networks that the research platform will feature, the scale of the networks, and the effort involved in setting up and maintaining a research platform of that scale. is a nonprofit organization that spurs the creation of next-generation applications and services that leverage advanced networking technologies that build the foundation for smart communities. one do research on the design and development of the research platforms, or only as part of research projects to be enabled by the research platforms?., from march 8), the ppo will develop a request for proposals (rfp) calling for teams of communities and research universities to propose the design, development, deployment, and initial operations of multiple platforms for advanced wireless research across the country. expect the research platforms to use a diverse set of spectrum bands depending on the types of wireless networks to be supported. the fcc website for receiving applications to this new experimental license is expected to be online by the time the proposals for platforms are due.

Proposal and evaluation for wireless sensor network which use

this consideration will take place in the context of the core focus of the research platforms (i. announcement of the subawardees for the first research platforms is anticipated in early 2018. what pawr’s research efforts could bring in the next decade. would you characterize the research platforms and how many will there be? first part of the pawr program is constituted by building the research platforms, which will involve a mix of engineering as well as research in infrastructure. allocations to nsf-supported researchers will advance fundamental knowledge in the long term, while allocations to industry researchers will accelerate nearer-term research and development activities. research platforms are expected to serve the research communities for a decade or more, but the individual research projects that will be conducted on the research platforms can be short-, medium-, and/or long-term. for-profit and non-profit partners are welcomed (and in fact, encouraged) to the extent that they enhance the capabilities, reach, and sustainability of a proposed research platform. ppo will collaborate closely with nsf, the wireless research community, local communities, and industry in the design, development, deployment, and initial operations of the research platforms. topics are not fixed; the expectation is that pis, industry, and communities will be able to refine and add to these research topics to ensure that they benefit the us wireless ecosystem. year, following receipt of proposals in response to the rfp, the ppo will run a merit review process, comparable to that of nsf, to evaluate the submitted proposals. he will oversee the process of research allocation on the platforms as well as the evolution of platform research focus over time.., a framework for the design of the research platforms), with input from nsf, the research community, and the industry consortium., non-profits are eligible to apply as leads for research platform proposals. in internet traffic place never-before-imagined demands on conventional 4g lte networks and public wifi networks, which may not be able to keep pace with the growing demand. the pawr effort aims to explore research at scale in real-world settings outside of the laboratory. we expect the research platform proposers to be aware of the federal communication commission’s (fcc) spectrum policies: the fcc has created a new program experimental license that will allow for testing on a wide swath of frequencies. year, the united states became the first country in the world to make vast quantities of high-frequency millimeter wave spectrum – frequencies that have the ability to send large amounts of data quickly but that don’t travel as far as the lower-frequency waves used today in 4g networks – available for both licensed and unlicensed use. topics are not fixed; the expectation is that pis, industry, and communities will be able to refine and add to these research topics to ensure that they benefit the us wireless ecosystem.

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carriers, device and equipment vendors, and researchers around the world are looking toward the next generation of wireless technologies (popularly called ‘5g’) and beyond to support this unparalleled growth in devices and traffic. announcement of the subawardees for the first research platforms is anticipated early next year (2018). for academic researchers or municipal leaders interested in submitting a pawr proposal, we anticipate hosting a proposers’ day in the washington, dc, area after the pawr rfp is announced. newly available millimeter wave spectrum, in combination with other spectrum already available, promises to enable faster speeds and increased capacity in future wireless networks. will oversee the overall pawr technical direction, platform architectures, and alignment with the pawr vision of developing a shared, open, usable, diverse experimental facility that will support groundbreaking research in wireless networking. similarly, ffrdcs and federal labs may participate in conducting experiments on the eventual research platforms. industry consortium members may not participate in platform proposals, given their role in funding the platforms; other companies may choose to collaborate directly with the individual proposers. spectrum to focus on the spectral bands that are sub-6ghz, and aim to identify spectral opportunities in existing networks and establish usage models for novel spectrum-driven applications, while also studying co-existence and protection issues.-at-scale to address larger issues with network-mobility from the transport to mac layers, including evaluation of large-scale, dense, heterogeneous wireless networks, including issues such as connection management, load balancing, and mobility management.., well beyond the typical three-year duration of an nsf research grant. is anticipated that the first set of platforms for advanced wireless research will be available for use by late 2019 or early 2020. is anticipated that initial research on the pawr platforms will address many novel wireless technologies and services. newly available millimeter wave spectrum, in combination with other spectrum already available, promises to enable faster speeds and increased capacity in future wireless networks. multiple universities form a team to apply for a research platform? conducted on pawr platforms will advance robust new wireless devices, communication techniques, networks, systems, and services that will revolutionize the nation’s wireless ecosystem. proposers of the research platforms are encouraged to consider incorporating support for research on these vital questions as part of their design, development, and deployment. experimental research platforms will allow researchers to validate cutting-edge technologies (e. the proposers will propose specific designs for the individual research platforms, utilizing that framework. platform for advanced wireless research project office (ppo) manages 0 million public-private partnership and will oversee the research platforms.thesis proposal - uhcl area: privacy protectionresearchers:Alessandro acquisti, laura brandimarte, jeff hancockartifact-freesanitization of insider-threat dataresearcher:Roy maxionas-if infinitely ranged integer modelresearch area: trustworthy computing platforms and devicescross cutting thrusts: software securityresearcher:Robert seacorda static approach to operating system security iv research area: trustworthy computing platforms and devicesresearcher:Karl craryattacking and defending unreliable hardwareresearch area: trustworthy computing platforms and devicescross cutting thrusts: threat analysis and modeling | next generation threat prediction and responseresearcher:Onur mutluattention economics in information rich environments research area: privacy protectioncross cutting thrusts: business risk analysis and economic implications | usable privacy and securityresearcher:Alessandro acquistiaudio captchas for authenticating human userscross cutting thrusts: usable privacy and securityresearcher:Luis von ahnaugmenting the wisdom of crowds for anti-phishingcross cutting thrusts: usable privacy and securityresearchers:Jason hong, bryan pendletonautomatic code generation for block cipherscross cutting thrusts: cryptographyresearchers:Markus püschelautomatic facial landmark annotation of facial imagesresearch area: security of cyber-physical systemsresearcher:Marios savvidesautomatic facial landmarkingresearch area: security of cyber-physical systemsresearcher:Marios savvidesautomatic tracking and iris recognition for rifle scoperesearch area: security of cyber-physical systemsresearcher:Marios savvidesautonomous trustworthy computing platforms and devicesresearch area: trustworthy computing platforms and devices | security of cyber-physical systems | mobilitycross cutting thrusts: software securityresearcher:Ole mengshoelavoiding user downtime due to setting & authenticating securityresearchers:Daniel siewiorek, asim smailagicbap: the binary analysis platformcross cutting thrusts: software securityresearchers:David brumley, andres jagerbasis for empowering business it managers cross cutting thrusts: threat analysis and modeling | business risk analysis and economic implicationsresearchers:Andrew moore, randall trzeciak, dawn cappellibehavior-based malware email filteringresearch area: trustworthy computing platforms and devicescross cutting thrusts: software securityresearchers:James hoe, jason hongbehavior-based mobility researchresearch area: mobilityresearchers:Patrick tague, joy zhangbeyond scada for electric power infrastructuresresearcher:Marija ilicbiometrics identification on robots and unmanned aerial vehicles (uavs)research area: security of cyber-physical systemsresearcher:Marios savvidesbridging the gap between systems security and language securityresearch area: trustworthy computing platforms and devicescross cutting thrusts: software securityresearchers:Jonathan mccunecampus navigationresearch area: privacy protection | mobilityresearchers:James morris, norman sadehcasual authenticationcross cutting thrusts: usable privacy and securityresearchers:Jason hong, eiji hayashicircuit-level secure-by-design digital integrated circuitsresearch area: trustworthy computing platforms and devicesresearcher:Ken maicircuit-level secure-by-design field programmable gate arraysresearch area: next generation secure and available networkscross cutting thrusts: software securityresearcher:Ken maicloud computing: establishing shared utility, informing assured cloud computing researchresearch area: survivable distributed systemsresearchers:Greg ganger, priya narasimhan, chuck cranor, garth gibson, julio lopez, david o'hallaroncollaborative mobile sensor network control with extremely noisy measurementsresearch area: mobility | security of cyber-physical systemsresearchers:Pei zhang, bruno sinopolicompiling epistemic specifications to secure distributed code cross cutting thrusts: software security | formal methodsresearcher:Frank pfenningcompositional securityresearch area: trustworthy computing platforms and devicescross cutting thrusts: formal methods | software securityresearchers:Anupam datta, limin jia, amit vasudevan, sagar chakicomprehensive security & privacy for next generation mobile networksresearch area: mobility | privacy protection | next generation secure and available networksresearcher:Patrick taguecompressed sensing for face recognitionresearch area: mobility | security of cyber-physical systemsresearcher:Vijayakumar bhagavatulacomputer-readable privacy policiescross cutting thrusts: usable privacy and securityresearcher:Lorrie cranorcontext-aware scalable authentication: using passive multi-factor sensing to facilitate authenticationresearch area: mobilitycross cutting thrusts: usable privacy and securityresearcher:Jason hongcontinuous authenticationresearch area: security of cyber-physical systemscross cutting thrusts: usable privacy and securityresearcher:Marios savvidescontinuous authentication of computer user: how to avoid computer tailgating and ensure computer securityresearch area: security of cyber-physical systemsresearcher:Marios savvidescontractual anonymityresearch area: trustworthy computing platforms and devices | privacy protectioncross cutting thrusts: cryptographyresearchers:David brumley, jonathan mccunecreating resilient protocols with data-oriented transportresearcher:Dave andersencross-layer self-configuration for secure and resilient networkingresearch area: next generation secure and available networkscross cutting thrusts: next generation threat prediction and responseresearcher:Patrick taguecrowdscanning: using crowdsourcing and static analysis to understand the privacy issues in smartphone apps research area: mobility | privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Jason hong, norman sadehcyber-security threats to industrial control systemsresearch area: trustworthy computing platforms and devices | security of cyber-physical systemsresearchers:Virgil gligor, soo bum leedata confidentiality, privacy, and securityresearch area: privacy protectioncross cutting thrusts: cryptographyresearcher:Stephen fienbergdeep software assurance: requirements, techniques, field experiencecross cutting thrusts: software securityresearchers:Jonathan aldrich, william scherlisdependably usable interfaces for security in the real world (renewal)research area: mobilityresearcher:Roy maxiondesigning security kernels for verificationresearch area: trustworthy computing platforms and devicesresearchers:Anupam datta, jonathan mccunedesign methodologies for security applicationscross cutting thrusts: formal methodsresearcher:Roy maxiondeterrence via intermittent auditingresearch area: next generation secure and available networksresearchers:Anupam datta, virgil gligordevelopment & evaluation of resource-aware configurable survivabilityresearcher:Priya narasimhandevelopment of de-identification tools for video surveillance dataresearchers:Jie yangdiagnosing and locating wireless disruptionresearch area: mobility | next generation secure and available networksresearchers:Srinivasan seshan, peter steenkiste, dave andersendifferentially-private synthetic dataset release for machine learning and clusteringresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearcher:Avrim blumdistributed security monitoring system for survivable networksresearch area: survivable distributed systemsresearcher:Hyong kimdistributed stream algorithms researchers:Christopher olstondynamically reconfigurable antenna arraysresearch area: trustworthy computing platforms and devicesresearchers:Jason lohn, derek lindeneffective trust indicatorsresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearcher:Lorrie cranorefficient, secure encryption implementationsresearch area: trustworthy computing platforms and devicescross cutting thrusts: cryptographyresearcher:Ken maiefficient and effective high speed network logging for digital forensicsresearch area: next generation secure and available networksresearcher:Dave andersenefficient data-intensive computing in support of security applications research area: next generation secure and available networks | survivable distributed systemscross cutting thrusts: next generation threat prediction and responseresearcher:Dave andersenefficiently securing non-volatile storage in portable systemsresearch area: mobility | trustworthy computing platforms and devices | secure home computingresearcher:Ken maiefficient trojan detection in field programmable gate arraysresearch area: trustworthy computing platforms and devicesresearchers:Shawn blatonempirical analysis of data breach litigationresearch area: privacy protectioncross cutting thrusts: business risk analysis and economic implicationsresearchers:Alessandro acquisti, sasha romanoskyempirically-based insider threat risk assessment diagnosticcross cutting thrusts: threat analysis and modeling | next generation threat prediction and responseresearchers:Andrew moore, dawn cappelliengineering self-healing systems to support trustworthy computingresearcher:David garlanenhancements to large-scale network monitoring for bot detectionresearch area: next generation secure and available networksresearchers:Marcus deshonenhancing dms software to secure electric power network serviceresearchers:Marija ilic, ozan tonguzevaluating and controlling personal privacy in smart environmentsresearch area: secure home computingresearchers:Patrick tague, anthony roweevaluating and improving browser encryptioncross cutting thrusts: software security | usable privacy and securityresearchers:Collin jackson, lin-shung huang, eric chenevolutionary roots of privacy and security concernsresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearcher:Alessandro acquistiexpanding firewall misconfiguration detection based on dynamic routing analysis for large networkresearch area: next generation secure and available networksresearcher:Hyong kimexploratory r&d of a technology-driven insider threat scoring metriccross cutting thrusts: next generation threat prediction and response | threat analysis and modelingresearchers:Andrew moore, randall trzeciakextracting security policies from source code research area: privacy protectionresearchers:Michael tschantzfast correlation filtering for biometric recognitionresearch area: security of cyber-physical systemscross cutting thrusts: cryptographyresearcher:Vijayakumar bhagavatulafault-tolerant voting cross cutting thrusts: formal methodsresearcher:Ryan o'donnellformalizing and enforcing privacyresearch area: privacy protectioncross cutting thrusts: formal methodsresearchers:Anupam datta, limin jia, jeremiah blocki, zeliha dilsun kaynar, divya sharma, arunesh sinha, michael tschantzfurther investigations into wireless broadcast researcher:Rohit negigames and links: combating web spam research area: trustworthy computing platforms and devicesresearcher:Manuel blumgort: an analysis tool for understanding the privacy and security behaviors of smartphone appsresearch area: mobility | privacy protectioncross cutting thrusts: usable privacy and securityresearcher:Jason honggrey project: device-enabled authorizationresearch area: mobility | secure home computingcross cutting thrusts: usable privacy and securityresearcher:Lujo bauerimpact of online social networks on hiring practices research area: privacy protectioncross cutting thrusts: business risk analysis and economic implicationsresearchers:Alessandro acquisti, christina fongimproved biometric encryption by using correlation filtersresearch area: security of cyber-physical systemscross cutting thrusts: cryptographyresearcher:Vijayakumar bhagavatulaimproving the security and usability of text passwordscross cutting thrusts: usable privacy and securityresearchers:Lorrie cranor, lujo bauer, nicolas christininference-based adaptation techniques for next generation jamming and anti-jamming capabilitiesresearch area: next generation secure and available networkscross cutting thrusts: next generation threat prediction and response | threat analysis and modelingresearcher:Patrick tagueinformation and influence propagation in social networksresearch area: next generation secure and available networksresearchers:Virgil gligor, osman yaganinherently trojan-resistant integrated circuit architecturesresearch area: trustworthy computing platforms and devicescross cutting thrusts: cryptographyresearcher:Ken maiinsider threat analysis centercross cutting thrusts: threat analysis and modeling | next generation threat prediction and responseresearchers:Andrew moore, randall trzeciak, dawn cappelliintegrated vehicle-network-vision system for transit securityresearcher:Yang caiintelligent video surveillance networks for critical infrastructuresresearch area: next generation secure and available networks | security of cyber-physical systemsresearcher:Raj rajkumarlockdown: a safe and practical environment for security applicationsresearch area: secure home computing | trustworthy computing platforms and devicesresearchers:Virgil gligor, adrian perrig, amit vasudevanlogical reasoning about obligationsresearch area: privacy protectioncross cutting thrusts: formal methodsresearcher:Frank pfenninglong range iris acquisition and recognitionresearch area: security of cyber-physical systemsresearcher:Marios savvideslong range stand-off iris recognitionresearch area: security of cyber-physical systemsresearcher:Marios savvidesmachine learning techniques for phishing attacksresearch area: trustworthy computing platforms and devices | privacy protectionresearcher:Jason hongmaking the support vector machine-based relays secureresearch area: next generation secure and available networksresearchers:Marija ilic, ozan tonguzmalicious fault-immune cryptographic hardware implementationcross cutting thrusts: cryptographyresearcher:Diana marculescumanagement & education of risks of insider threat (merit)researchers:Andrew moore, dawn cappellimeasuring and modeling security and privacy laws research area: privacy protectioncross cutting thrusts: business risk analysis and economic implicationsresearchers:Alessandro acquisti, sasha romanosky, richard sharpmerit itl: the insider threat labcross cutting thrusts: business risk analysis and economic implications | threat analysis and modeling | next generation threat prediction and responseresearchers:Andrew moore, randall trzeciak, dawn cappellimixed effects models for predicting anomaly-detector error ratesresearch area: security of cyber-physical systemsresearcher:Roy maxionmobile platform securityresearch area: mobilitycross cutting thrusts: software security | formal methodsresearchers:Lujo bauer, limin jiamobile users effectively control privacy in a friend-finder applicationresearch area: mobility | privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Norman sadeh, lorrie cranor, jason hongmulti-biometric authentication system (mbas)researcher:Vijayakumar bhagavatulamulti-biometrics for security & surveillanceresearch area: security of cyber-physical systemsresearchers:Marios savvides, keshav thirumalai seshadri, shreyas venugopalan, taihei munemotomultibiometric signal exploitation, analysis and accelerationresearch area: security of cyber-physical systemsresearcher:Marios savvidesmultichannel modeling for enhancing and masking speech communicationsresearch area: mobilitycross cutting thrusts: usable privacy and securityresearchers:Ted selker, ian lanemulti-modal biometric sensor networksresearcher:Marios savvidesmulti-modal biometric verificationresearch area: security of cyber-physical systemsresearcher:Vijayakumar bhagavatulanext generation available internetresearch area: trustworthy computing platforms and devices | next generation secure and available networksresearchers:Virgil gligor, adrian perrig, soo bum leenext-generation binary analysis techniques and platform cross cutting thrusts: software security | formal methodsresearcher:David brumleyone-finger, two-factor authentication with number padsresearch area: security of cyber-physical systemsresearcher:Roy maxiononline crime economics: modeling advertising and retail operationscross cutting thrusts: business risk analysis and economic implications | threat analysis and modelingresearcher:Nicolas christinon privacy and complianceresearch area: privacy protectioncross cutting thrusts: cryptographyresearchers:Anupam datta, zeliha dilsun kaynaropen source & outsourced software acceptance evaluation & assuranceresearchers:James herbsleb, jonathan aldrichopen source evaluation and assurancecross cutting thrusts: software security | formal methodsresearcher:William scherlispasisresearcher:Greg gangerpassword-composition policies and the security and usability of passwordsresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Lujo bauer, nicolas christin, lorrie cranorpasswordscross cutting thrusts: usable privacy and securityresearchers:Lujo bauer, lorrie cranor, nicolas christinpath inference in data center networksresearch area: next generation secure and available networksresearcher:Hyong kimpersonal information revelation in online social networksresearch area: privacy protectionresearcher:Alessandro acquistipersonal information security, conflation of dissemination and access, and illusion of controlresearch area: privacy protectioncross cutting thrusts: business risk analysis and economic implicationsresearcher:Alessandro acquistiphysiological activity recognition system (pars)research area: mobilityresearcher:Pei zhangpi (path identifier) packet marking scheme researcher:Adrian perrigprincipled approach to web securitycross cutting thrusts: software security | formal methodsresearchers:Anupam datta, limin jia, deepak gargprivacy, audit and accountabilityresearch area: privacy protectionresearchers:Anupam datta, limin jiaprivacy, information disclosure, & authorization from a logical perspectiveresearchers:Frank pfenning, lujo bauerprivacy and security in real time monitoring systemsresearch area: mobility | privacy protectionresearchers:Daniel siewiorek, asim smailagic, martin grissprivacy and the illusion of controlresearch area: privacy protectionresearchers:Alessandro acquisti, laura brandimarte, george lowensteinprivacy and usability in pervasive computing environmentscross cutting thrusts: usable privacy and securityresearchers:Norman sadeh, lujo bauerprivacy decision-makingresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Lorrie cranor, alessandro acquistiprivacy notice and choice in practiceresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearcher:Lorrie cranorprivacy nudgingresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Alessandro acquisti, lorrie cranor, norman sadehprobabilistic verification of security properties in self-adaptive systemscross cutting thrusts: software securityresearcher:David garlanprocess variation-aware modeling, analysis, and prevention of thermal attacks in many-core systemsresearch area: trustworthy computing platforms and devicescross cutting thrusts: threat analysis and modelingresearcher:Diana marculescuproposal: trust-free garbage collection for mobile coderesearch area: survivable distributed systemsresearcher:Karl craryprotecting browsers from mixed content injection attackscross cutting thrusts: software security | usable privacy and securityresearchers:Collin jacksonprotecting privacy and confidentiality of informationresearch area: privacy protectionresearcher:Rahul telangprototyping security applications for ambient intelligenceresearcher:Radu marculescuproviding privacy & authenticationresearch area: privacy protectionresearcher:Rohit negirecognition of challenging ocular imagesresearch area: security of cyber-physical systemsresearcher:Vijayakumar bhagavatulareconciling privacy and usability by learning default privacy policiesresearch area: privacy protection | mobilitycross cutting thrusts: usable privacy and securityresearcher:Norman sadehresponse to software vulnerabilitiescross cutting thrusts: software securityresearchers:Ashish arorarfmaster: rfid-based secure access to physical spacesresearcher:Raj rajkumarrisk analysis for securing wireless ad-hoc networks research area: mobility | next generation secure and available networksresearcher:Radu marculescurobust, optimal design of interdependent, multi-layer, and multiplex networksresearch area: next generation secure and available networksresearcher:Osman yaganrobust, secure, efficient cyber-physical systemsresearch area: security of cyber-physical systemscross cutting thrusts: threat analysis and modelingresearcher:Norman sadehrobust, secure, efficient networked embedded control systemsresearch area: trustworthy computing platforms and devices | mobilitycross cutting thrusts: software securityresearcher:Bruno sinopolirobust connectivity in the presence of insecure and unreliable links in ad-hoc networksresearch area: next generation secure and available networksresearchers:Virgil gligor, osman yaganrobust iris & face acquisition at 8-13m for the war-fighterresearch area: security of cyber-physical systemsresearcher:Marios savvidesrobust multi-biometrics identification using soft-biometric intelligenceresearch area: security of cyber-physical systemsresearcher:Marios savvidessaf: applying assurance to the survivability analysis frameworkresearch area: survivable distributed systemssaferideresearch area: mobilityresearcher:James morrissafeslinger: easy-to-use and secure public-key exchangeresearch area: mobilitycross cutting thrusts: usable privacy and security | cryptographyresearchers:Michael farb, adrian perrig, jonathan mccune, tiffany hyun-jin kim, yue-hsun linscion: scalability, control, and isolation on next-generation networksresearch area: trustworthy computing platforms and devices | next generation secure and available networksresearchers:Adrian perrig, dave andersen, virgil gligor, soo bum leesecurable, usable context toolkit for mobile applicationsresearch area: mobilitycross cutting thrusts: usable privacy and securityresearchers:Martin griss, anind dey, pei zhang, joy zhangsecure, reliable, efficient physical unclonable functionsresearch area: trustworthy computing platforms and devicescross cutting thrusts: cryptographyresearcher:Ken maisecure access to buildings using rfid technologies & video loggingresearcher:Raj rajkumarsecure ad hoc routing protocolsresearch area: mobilityresearcher:Adrian perrigsecure broadcast communication: in wired and wireless networksresearch area: next generation secure and available networksresearcher:Adrian perrigsecure communication in sensor networksresearch area: next generation secure and available networksresearcher:Adrian perrigsecure concurrent distributed programmingcross cutting thrusts: software security | formal methodsresearcher:Frank pfenningsecure digital homeresearch area: secure home computingcross cutting thrusts: usable privacy and securityresearchers:Lujo bauer, greg ganger, lorrie cranorsecure distributed logic programmingcross cutting thrusts: formal methods | software securityresearcher:Frank pfenningsecure home storageresearch area: secure home computingcross cutting thrusts: usable privacy and securityresearchers:Lujo bauer, lorrie cranor, greg gangersecure network & communication infrastructureresearch area: next generation secure and available networksresearcher:Ozan tonguzsecure routing in sensor networksresearcher:Adrian perrigsecure sensor networksresearch area: next generation secure and available networksresearcher:Adrian perrigsecure software development and operationcross cutting thrusts: software security | formal methodsresearchers:David brumley, maverick woo, manuel egelesecuring the digital homeresearch area: secure home computingcross cutting thrusts: usable privacy and securityresearchers:Lujo bauer, lorrie cranor, greg ganger, adrian perrigsecurity and privacy risk management in organizationscross cutting thrusts: business risk analysis and economic implicationsresearchers:Nicolas christin, anupam dattasecurity behavior observatoryresearch area: secure home computing | privacy protectioncross cutting thrusts: software security | usable privacy and security | threat analysis and modelingresearchers:Alessandro acquisti, nicolas christin, lorrie cranor, rahul telangsecurity for cloud clients with rich controlled sharingresearchers:Virgil gligor, adrian perrig, james newsome, jonathan mccune, collin jackson, eric chensecurity issues in information namingresearch area: secure home computing | survivable distributed systemscross cutting thrusts: next generation threat prediction and responseresearcher:Srinivasan seshansecurity patterns: assurance for secure concurrent and distributed computingcross cutting thrusts: software security | next generation threat prediction and response | formal methodsresearchers:William scherlis, jonathan aldrichsecurity quality requirements engineering (square) projectcross cutting thrusts: formal methods | software securityresearchers:Nancy mead, lorrie cranorself-configuring wireless networksresearchers:Srinivasan seshan, peter steenkisteself-securing devicesresearcher:Greg gangerself-securing storageresearcher:Greg gangersemantic geotagging for situational awareness during disaster responseresearch area: mobility | trustworthy computing platforms and devicescross cutting thrusts: usable privacy and securityresearchers:Martin griss, anind dey, ray bareiss, steven rosenberg, joy zhangsemantic web reasoning technologies for web privacyresearcher:Norman sadehsensibleintegrating sensing & processingresearcher:Diana marculescusensor network security monitoring and management systemresearch area: next generation secure and available networksresearcher:Adrian perrigsimplifying access control for home networkingresearch area: privacy protection | security of cyber-physical systemsresearchers:Jason hong, bryan pendletonsimplifying logins with web ticketresearch area: privacy protection | security of cyber-physical systemsresearchers:Jason hong, eiji hayashisluice: secure software upgrades in sensor networksresearch area: next generation secure and available networks | mobilityresearchers:Priya narasimhan, michael chuangsmart meters and their impact on residential privacyresearch area: security of cyber-physical systems | privacy protectionresearcher:Anthony rowesoft-biometricsresearch area: security of cyber-physical systemsresearcher:Marios savvidessoft biometrics from emerging mediaresearch area: security of cyber-physical systemsresearchers:Yang cai, mel siegel, brian zeleznik, rich noland, alex nicollsoftware-based attestation for peripheralsresearch area: trustworthy computing platforms and devicescross cutting thrusts: software security | threat analysis and modelingresearchers:Adrian perrig, jonathan mccunespartacusresearch area: mobilityresearcher:Pei zhangsquare: requirements engineering for improved system securityresearch area: trustworthy computing platforms and devicescross cutting thrusts: formal methodsresearcher:Nancy meadstarfish: scalable survivable middlewareresearcher:Priya narasimhanstatistical methodology and disclosure limitationresearcher:Stephen fienbergstudying the android malware ecosystemresearch area: mobilitycross cutting thrusts: software securityresearcher:Nicolas christinsuper-resolution for iris recognitionresearch area: security of cyber-physical systemsresearcher:Vijayakumar bhagavatulasupporting trust decisionsresearchers:Lorrie cranor, norman sadehsurvivable distributed storage: from theory to realityresearch area: survivable distributed systemsresearchers:Greg ganger, manish prasadsurviving network partitioning in distributed wireless systemsresearch area: survivable distributed systemsresearcher:Priya narasimhansystem integrity manager for the everyday usersresearch area: secure home computingcross cutting thrusts: usable privacy and securityresearchers:Hyong kim, james hoesystem quality requirements engineering process (square)researcher:Nancy meadtargeted software assuranceresearch area: survivable distributed systemscross cutting thrusts: software security | formal methodsresearchers:William scherlis, jonathan aldrichtechniques for compositional security: foundations, mechanized reasoning and applicationsresearch area: trustworthy computing platforms and devicescross cutting thrusts: formal methods | software securityresearchers:Anupam datta, limin jia, deepak-gargthe captcha projectresearchers:Manuel blum, luis von ahnthe dragnet system for network forensic analysisresearcher:Hui zhangthe economic incentive to improve software securityresearchers:Rahul telang, ashish arorathe tesla broadcast authentication protocolresearcher:Adrian perrigthree-dimensional craniofacial modeling for novel two-dimensional pose synthesis and age progressionresearch area: security of cyber-physical systemsresearcher:Marios savvidestransient customization of mobile computing infrastructureresearch area: mobilityresearcher:Mahadev satyanarayanantrinetra: mobile technologies for assisting the blind & visually impairedresearch area: mobility | secure home computingresearchers:Priya narasimhan, moshe mahlertrusted computingresearch area: trustworthy computing platforms and devicesresearchers:Anupam datta, adrian perrig, virgil gligor, amit vasudevantrust establishment in interactive human protocols over the internetresearch area: trustworthy computing platforms and devicesresearchers:Virgil gligor, adrian perrig, tiffany hyun-jin kimtrustworthy computing platforms and devicesresearch area: trustworthy computing platforms and devicesresearchers:Virgil gligor, anupam datta, adrian perrig, amit vasudevan, limin jiatrustworthy execution environments on mobile devicesresearch area: trustworthy computing platforms and devicescross cutting thrusts: software security | threat analysis and modelingresearchers:Amit vasudevan, adrian perrig, james newsome, jonathan mccuneunderstanding human behaviors at large scales through mobile devicesresearch area: mobility | privacy protection | security of cyber-physical systemsresearchers:Jason hong, norman sadeh, justin cranshaw, eran tochunderstanding user investments & response to security threatscross cutting thrusts: threat analysis and modeling | business risk analysis and economic implicationsresearcher:Nicolas christinusable cyber trust indicatorsresearch area: privacy protectioncross cutting thrusts: usable privacy and securityresearcher:Lorrie cranorusable security and privacy for context-aware mobile applicationsresearch area: mobilitycross cutting thrusts: usable privacy and securityresearchers:Martin griss, anind dey, pei zhanguser-controllable policy learningresearch area: mobility | privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Norman sadeh, lorrie cranoruser controllable security & privacy for mobile social networkingresearch area: mobility | privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Norman sadeh, lorrie cranor, jason honguser-controllable security and privacy for pervasive computingresearch area: privacy protection | mobilitycross cutting thrusts: usable privacy and securityresearchers:Norman sadeh, jason hong, lorrie cranor, lujo baueruse your illusion: using visual distortion to secure image-based authenticationcross cutting thrusts: usable privacy and securityresearchers:Jason hong, nicolas christin, eiji hayashiusing personalized face composites for visceral targetingresearch area: privacy protectionresearchers:Alessandro acquisti, ralph gross, sonam samat, eyal pe'ervajra: benchmarking survivability in distributed systemsresearcher:Priya narasimhanverifiable properties of computations outsourced to the cloudcross cutting thrusts: cryptographyresearchers:Virgil gligor, anupam datta, amit vasudevanvisualizing home networksresearch area: secure home computingcross cutting thrusts: usable privacy and securityresearcher:Jason hongvma: dynamic and secure heterogeneous system for elder careresearch area: next generation secure and available networks | mobility | privacy protectioncross cutting thrusts: usable privacy and securityresearchers:Pei zhang, martin griss, raj rajkumar, daniel siewiorek, asim smailagicwireless sensor networks for people-trackingresearch area: next generation secure and available networks | security of cyber-physical systemsresearcher:Raj rajkumarwireless video sensor networks for security applicationsresearcher:Radu marculescuxtrec: secure real-time execution trace recording and analysis on commodity platformsresearch area: trustworthy computing platforms and devices | security of cyber-physical systemscross cutting thrusts: software securityresearchers:Adrian perrig, virgil gligor, amit vasudevan. are several problems of interest to rural areas that a small city/community may consider tackling as part of a research platform.-area whitespace to utilize novel whitespace-based wireless networks to design, build and demonstrate 1gbps connectivity to remote locations via long-range wireless mesh connections. this consideration will take place in the context of the core focus of the research platforms (i. it is anticipated that each subsequently-funded research platform will comprise a city-university team; this team may also involve corporate partners, ffrdcs, and federal labs. allocation of time will be shared equally between industry and nsf-supported academic researchers and will be complementary. you envision following an approach by which experiments to be run on the research platforms are vetted in some way to determine their suitability? nsf nor the ppo will predefine the research foci for the research platforms. the research topic areas listed above the only areas of research nsf is interested in funding for the research platforms? is anticipated that the first set of platforms for advanced wireless research will be available for use by late 2019 or early 2020. however, note that nsf funding to ffrdcs and federal labs is provided only under unique circumstances, as specified in nsf’s proposal & award policies & procedures guide (see https://nsf. is anticipated that the first set of platforms for advanced wireless research will be available for use by late 2019 or early 2020. will heterogeneity, security and privacy, and coexistence be addressed in these research platforms? ppo is responsible for allocating and managing time for experimentation on the platforms for advanced wireless research. what spectrum bands are the research platforms expected to operate, and will there be a need for licensing? we expect the research platform proposers to be aware of the federal communication commission’s (fcc) spectrum policies: the fcc has created a new program experimental license that will allow for testing on a wide swath of frequencies. the last year, a new industry consortium comprising more than 25 leading networking vendors, device manufacturers, and wireless carriers has been established to support the pawr effort, garnering approximately million in cash and in-kind contributions. as a reminder, project proposals must clearly demonstrate that the chosen lead is the most capable to follow through on the design, development, and deployment of the proposed research platform. each research platform will also have an external user advisory council to provide continued inputs on the research scope and foci of the platforms during the operations of the platforms. 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with any system, there will be a learning curve – but it is anticipated that the research platforms will have staff and tutorials to assist users and mitigate this learning curve. companies will benefit by: helping to sustain us industry leadership; shaping design of research platforms; and securing cutting-edge research returns well in excess of initial investment. science foundation and northeastern university to spend 0 million on advanced wireless research. pawr project office will collaborate closely with nsf, the wireless research community, local communities, and industry in the design, development, deployment, and initial operations of the research platforms. and beyond: national science foundation plunks down million for advanced wireless research. platforms for advanced wireless research (pawr) program is jointly supported by the national science foundation and a wireless industry consortium to create community-scale research platforms to accelerate fundamental research on wireless communication and networking technologies. existing ideas that have been successfully demonstrated in the laboratory environment will be able to use the envisioned research platforms to demonstrate viability at scale.., a framework for the design of the research platforms), with input from nsf, the research community, and the industry consortium. both the pawr industry consortium and nsf seek to explore a multitude of research concepts through these research platforms. the psc will consist of leaders in wireless research from academic, industry, government, and communities across the us. will be given to the positive impacts of a given research platform on the community proposing to host it – not only in terms of potential pilot deployments of advanced technologies, but also with respect to jobs, workforce development, and economic competitiveness, for example. what pawr’s research efforts could bring in the next decade. allocations to nsf-supported researchers will advance fundamental knowledge in the long term, while allocations to industry researchers will accelerate nearer-term research and development activities. proposers are expected to obtain such licenses and include these as part of their proposals to validate the feasibility of the proposed research platforms to work in the bands to be supported. the psc will consist of leaders in wireless research from academic, industry, government, and communities across the us. for research on top of the platforms will be separate from the funding for the platforms. a city or a university may lead a proposing team; each proposal must make the case that the lead is capable of following through on the design, development, deployment, and operation of the proposed research platform. intent is for the research platforms to feature both open hardware and open software interfaces, and to be reusable by others. will be given to the positive impacts of a given research platform on the community proposing to host it – not only in terms of potential pilot deployments of advanced technologies, but also with respect to jobs, workforce development, and economic competitiveness, for example. Write a business plann | Research and Academics | Cisco Research Center pawr will enable experimental exploration of robust new wireless devices, communication techniques, networks, systems, and services that will revolutionize the nation’s wireless ecosystem, thereby enhancing broadband connectivity, leveraging the emerging internet of things (iot), and sustaining us leadership and economic competitiveness for decades to come. pawr industry consortium members are not eligible to be named participants on any research platform proposal. allocation of time will be shared equally between industry and nsf-supported academic researchers and will be complementary., these pawr research efforts will accelerate the deployment of a new generation of super-fast, ultra-low latency, high-capacity networks will enable breakthrough applications for consumers, smart cities, and the internet of things that cannot even be imagined today. as a reminder, project proposals must clearly demonstrate that the chosen lead is the most capable to follow through on the design, development, and deployment of the proposed research platform. for research on top of the platforms will be separate from the funding for the platforms. for academic researchers or municipal leaders interested in submitting a pawr proposal, we anticipate hosting a proposers’ day in the washington, dc, area after the pawr rfp is announced. industry receive funding from nsf if collaborating on the research platform proposal? is anticipated that the first set of platforms for advanced wireless research will be available for use by late 2019 or early 2020. expect the research platforms to use a diverse set of spectrum bands depending on the types of wireless networks to be supported. we only think about short-term (three years or less until commercialization) projects to evaluate on the research platforms envisioned in the pawr: ppo program solicitation?-at-scale to address larger issues with network-mobility from the transport to mac layers, including evaluation of large-scale, dense, heterogeneous wireless networks, including issues such as connection management, load balancing, and mobility management. local corporate sponsors participate in the city-university research platform (design, development, and deployment) proposals? is anticipated that initial research on the pawr platforms will address many novel wireless technologies and services. existing ideas that have been successfully demonstrated in the laboratory environment will be able to use the envisioned research platforms to demonstrate viability at scale. will seek proposed platforms that have the capability to support a minimum number of research topic areas (e. however, note that nsf funding to ffrdcs and federal labs is provided only under unique circumstances, as specified in nsf’s proposal & award policies & procedures guide (see https://nsf. as the research platforms mature over time, they will support less research in the design and development aspects and more research as a result of the availability of the infrastructure. to test data network architectures for next-generation networks that operate with a wireless edge. Write a short note on following conditional operator in c | framework for wireless network security using quantum cryptography there an expectation that the research conducted on the platforms will inherently lead to commercialization in the short term? the research platforms are meant to support fundamental, pre-competitive academic research, for which impacts may very well be realized 10 or more years into the future, i. pawr will enable experimental exploration of robust new wireless devices, communication techniques, networks, systems, and services that will revolutionize the nation’s wireless ecosystem, thereby enhancing broadband connectivity, leveraging the emerging internet of things (iot), and sustaining us leadership and economic competitiveness for decades to come. there been thought as to how to make the research platforms “living”/dynamically adaptable? note that we intend for these research platforms to enable fundamental, pre-competitive research on topics that will support advanced wireless networking innovations, along with potential competitive research led by members of the industry consortium. platforms for advanced wireless research (pawr) rfp is now live! industry receive funding from nsf if collaborating on the research platform proposal?., from march 8), the ppo will develop a request for proposals (rfp) calling for teams of communities and research universities to propose the design, development, deployment, and initial operations of multiple platforms for advanced wireless research across the country. answer to this question may vary depending on the goals and scope of each individual research platform. both the pawr industry consortium and nsf seek to explore a multitude of research concepts through these research platforms. anticipates supporting the academic community to conduct fundamental research atop the platforms beginning in early 2020. anticipates supporting the academic community to conduct fundamental research atop the platforms beginning in early 2020. the research topic areas listed above the only areas of research nsf is interested in funding for the research platforms? will heterogeneity, security and privacy, and coexistence be addressed in these research platforms? for a given research platform, the geographic area will be a function of the type of wireless networks that the research platform will feature, the scale of the networks, and the effort involved in setting up and maintaining a research platform of that scale. relating to the research to be enabled by the research platforms:Is it incumbent on potential users to learn how to use the research platform interfaces or will there be tutorials created/support provided? science foundation and northeastern university to spend 0 million on advanced wireless research. participating communities will benefit by: building core wireless capabilities through creative university partnerships; attracting government and corporate research funding and local wireless jobs; and utilizing advanced wireless capabilities to enhance city services and economic development.., well beyond the typical three-year duration of an nsf research grant. Advantages of being the only child essay | Platforms for Advanced Wireless Research (PAWR) Project Office allocation of time will be shared equally between industry and nsf-supported academic researchers and will be complementary. anticipates issuing a solicitation calling for proposals from the academic community to support basic research on the platforms by early 2020. we have provided sample research areas, but these are meant to be only examples., staying current with rapidly evolving technologies will be essential to the long-term utility and success of the research platforms, including sustenance. year, the united states became the first country in the world to make vast quantities of high-frequency millimeter wave spectrum – frequencies that have the ability to send large amounts of data quickly but that don’t travel as far as the lower-frequency waves used today in 4g networks – available for both licensed and unlicensed use. announcement of the subawardees for the first research platforms is anticipated in early 2018. pawr project office will collaborate closely with nsf, the wireless research community, local communities, and industry in the design, development, deployment, and initial operations of the research platforms. do you maintain mid- and long-term research projects while also accounting for public interest and the need to translate innovations to the marketplace quickly in order to justify local investment? deployed, the platforms will address pre-competitive research challenges on at-scale research platforms, increasing education about wireless technologies and data networking, increasing academic-industry cooperative partnerships, and accelerating technology commercialization and transfer from academia to industry. there any expectations as far as open interfaces for the research platforms? ppo is responsible for allocating and managing time for experimentation on the platforms for advanced wireless research. year, following receipt of proposals in response to the rfp, the ppo will run a merit review process, comparable to that of nsf, to evaluate the submitted proposals. platform for advanced wireless research project office (ppo) manages 0 million public-private partnership and will oversee the research platforms. ppo is responsible for allocating and managing time for experimentation on the platforms for advanced wireless research. ppo will collaborate closely with nsf, the wireless research community, local communities, and industry in the design, development, deployment, and initial operations of the research platforms. participating communities will benefit by: building core wireless capabilities through creative university partnerships; attracting government and corporate research funding and local wireless jobs; and utilizing advanced wireless capabilities to enhance city services and economic development. allocations to nsf-supported researchers will advance fundamental knowledge in the long term, while allocations to industry researchers will accelerate nearer-term research and development activities. designing, developing, deploying, and operating the platforms for advanced wireless research:The ppo, in conjunction with the pawr industry consortium and nsf, is developing a request for proposals (rfp) that will call for teams of communities and research universities to propose the design, development, deployment, and initial operations of multiple platforms for advanced wireless research across the country. as the research platforms mature over time, they will support less research in the design and development aspects and more research as a result of the availability of the infrastructure.

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